DOCSLIB.ORG

Stephen F. Heinemann Obituary

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Stephen F. Heinemann Obituary Newswise Keywords: Obituary, Neuroscience, Scientists Stephen F. Heinemann, Pioneering Salk Molecular Neuroscientist, Dies at 75 Salk professor’s work on neurotransmitter receptors opened the door to understanding learning, memory and diseases of the nervous system Salk Institute for Biological Studies Released: 8-Aug-2014 5:00 PM EDT Stephen Heinemann Source Newsroom: Salk Institute for Biological Studies more news from this source Contact Information Available for logged-in reporters only Newswise — Stephen F. Heinemann, whose pioneering research on neurotransmitter receptors in the brain helped lay the groundwork for understanding diseases that undermine learning and memory, died August 6 of complications of kidney failure at Vibra Hospital in San Diego, California. He was 75. A professor of neuroscience at the Salk Institute in La Jolla, California, Heinemann focused his research on the molecular mechanisms by which nerve cells communicate with each other at specialized connections known as “synapses.” Groundbreaking findings from his laboratory supported the idea that many diseases of the brain result from deficits in communication between nerve cells, and he was widely considered one of the world’s most accomplished researchers on learning and memory. “Steve was a giant of twentieth century neuroscience,” says William Brody, president of the Salk Institute. “His discoveries opened many avenues to better understand the function of the brain and for pursuing new therapies for neurological disorders.” Heinemann was born in Boston on February 11, 1939, to parents Robert B. Heinemann, a secondary school teacher and counselor, and Christel Fuchs Holtzer. He received his first chemistry set from his uncle, Emil Julius Klaus Fuchs, a theoretical physicist who contributed to the development of the atom bomb as part of the Manhattan Project, but later confessed to spying for the Soviet Union. Heinemann earned a bachelor of science degree from the California Institute of Technology in 1962 and a PhD in biochemistry from Harvard University in 1967. Subsequently, he completed postdoctoral studies at the Massachusetts Institute of Technology and Stanford University School of Medicine. In 1970, Heinemann was invited to join the core faculty of the Salk Institute in La Jolla, and was among its very first neuroscientists. There, he established the Salk Institute’s Molecular Neurobiology Laboratory, a program that by the late 1980s was ranked number one in the world. Among his many notable achievements, Heinemann and his team identified the genes encoding the major excitatory neurotransmitter receptors in the brain—those that are activated by glutamate and acetylcholine—and figured out how these receptors work. “His discoveries established the basic molecular rules for how nerve signals are conveyed from one neuron to the next,” says Greg Lemke, a professor of molecular neuroscience at Salk. “It is difficult to overstate the importance of this science—both for our understanding of how brains process information normally, and for how things can go wrong in neuropsychiatric and neurodegenerative disease.” The research for which Heinemann was best known was his discovery and analysis of glutamate receptors, which comprise the most important neurotransmitter receptor system in the brain. A key finding from this work was that deficits in the expression or activity of these receptors account for a variety of human psychiatric maladies, including schizophrenia and bipolar disorder. The conditions that Heinemann studied—which also included Alzheimer’s and Parkinson’s—are each fundamentally disorders of brain cell communication. With his team, Heinemann worked to find the molecular basis for this communication breakdown. Observing the aging of the country’s population, Heinemann often warned that an Alzheimer’s epidemic threatened to swamp the medical system. He led investigations into the brain’s receptors for nicotine—the group of receptors that is activated by the nicotine in tobacco and that may be damaged in Alzheimer’s disease. http://newswise.com/articles/view/621780?print-article[8/11/2014 9:02:12 AM] Newswise His research suggested that when the receptor alpha-7 encountered beta amyloid, the toxic protein found in the disease's hallmark plaques, the two could go rogue, thereby exacerbating Alzheimer's symptoms. Later studies identified the specific mechanical process by which neuronal communication became overwhelmed and broke down, leading to the memory loss and confusion typical of Alzheimer’s. This understanding gave pharmaceutical companies a new therapeutic target to explore. While conducting early research into the nicotinic receptors, Heinemann also uncovered the mechanism underlying the paralysis caused by myasthenia gravis, an autoimmune neuromuscular disease. In this disorder, antibodies target the nicotinic acetylcholine receptors of muscle cells. Because this interaction degrades the receptors, the cells are no longer able to respond to acetylcholine signals delivered from nerves to muscles, resulting in muscle paralysis and death. On the basis of Heinemann’s findings, pharmaceutical companies began designing new strategies to treat the disease. Heinemann held several patents and was honored by numerous awards in his lifetime. He was a member of the National Academy of Sciences, the National Institute of Medicine, and the American Academy of Arts and Sciences, and was a former President of the Society for Neuroscience. He received the Bristol-Myers Squibb Distinguished Achievement in Neuroscience Research Award and the McKnight Award for Research. In 2010, he was awarded the Julius Axelrod Prize for exceptional achievements in neuropharmacology and exemplary efforts in mentoring young scientists. He is survived by his wife of 54 years, Ann Reischauer Heinemann; his sons, Nate (Suzi), Danny (Cindy), Quentin (Rachel) and Tad; a daughter, Eden Westgarth (John); sisters Marcia Saunders, Kristel Heinemann, Marianna Holzer and Heidi Holzer; and 12 grandchildren. ©2014 Newswise, Inc. 215 5th St. SW, Suite 100, Charlottesville VA 22903 434-296-9417 Privacy Notice Terms of Servic http://newswise.com/articles/view/621780?print-article[8/11/2014 9:02:12 AM].
Load more

Recommended publications
  • Survival and Differentiation of Adult Neuronal Progenitor Cells Transplanted to the Adult Brain FRED H
    Proc. Natl. Acad. Sci. USA Vol. 92, pp. 11879-11883, December 1995 Neurobiology Survival and differentiation of adult neuronal progenitor cells transplanted to the adult brain FRED H. GAGE*t, PENELOPE W. COATESt, THEO D. PALMER*, H. GEORG KUHN*, LISA J. FISHER*, JAANA 0. SUHONEN*, DANIEL A. PETERSON*, STEVE T. SUHR*, AND JASODHARA RAY* *Laboratory of Genetics, The Salk Institute for Biological Studies, 10010 North Torrey Pines Road, La Jolla, CA 92037; and tDepartment of Cell Biology and Biochemistry, Texas Tech University Health Sciences Center, Lubbock, TX 79430 Communicated by Stephen Heinemann, The Salk Institute for Biological Studies, La Jolla, CA, August 22, 1995 ABSTRACT The dentate gyrus ofthe hippocampus is one exploring cues that influence the proliferation and differenti- of the few areas of the adult brain that undergoes neurogen- ation of neuronal progenitor cells and for neuronal replace- esis. In the present study, cells capable of proliferation and ment strategies for the damaged brain. neurogenesis were isolated and cultured from the adult rat hippocampus. In defined medium containing basic fibroblast growth factor (FGF-2), cells can survive, proliferate, and MATERIALS AND METHODS express neuronal and glial markers. Cells have been main- Cell Culture Conditions. Adult (>3 months) female Fischer tained in culture for 1 year through multiple passages. These 344 rats were anesthetized with a mixture of ketamine (44 cultured adult cells were labeled in vitro with bromodeoxyuri- mg/kg), acepromazine (0.75 mg/kg), and xylozine (4 mg/kg) dine and adenovirus expressing ,i-galactosidase and were in 0.9% NaCl and sacrificed in accordance with procedures transplanted to the adult rat hippocampus.
    [Show full text]
  • Degradation of Junctional and Extrajunctional Acetylcholine
    Proc. Natl. Acad. Sci. USA Vol. 76, No. 7, pp. 3547-3551, July 1979 Neurobiology Degradation of junctional and extrajunctional acetylcholine receptors by developing rat skeletal muscle (synapse development) JOE HENRY STEINBACH*, JOHN MERLIEt, STEPHEN HEINEMANN*, AND ROBERT BLOCH* *Neurobiology Department, The Salk Institute, P. 0. Box 1809, San Diego, California 92112; and tDepartment of Biological Science, University of Pittsburgh, Pittsburgh, Pennsylvania 15260 Communicated by Stephen W. Kuffler, April 20, 1979 ABSTRACT We have examined the rate of degradation of studied this question more thoroughly in diaphragms from rats, the total acetylcholine receptor content of diaphragm muscles 1 day old to adult, and found that junctional AcChoRs are of young rats and have found that even in muscles from 1-day- metabolically more stable than extrajunctional AcChoRs at all old rats some receptors are metabolically more stable than adult extrajunctional receptors. Further experiments have shown that ages examined. acetylcholine receptors at junctional regions from young rats are degraded slowly, whereas those in extrajunctional regions MATERIALS AND METHODS are degraded rapidly. The results demonstrate that junctional Preparation of t25I-Labeled a-Bungarotoxin. a-Bungaro- acetylcholine receptors in rat diaphragm are degraded at a slow rate characteristic of adult junctional receptors at all ages after toxin was purified from the venom of the krait Bungarus birth. multicinctus (Ross Allen Serpentarium, Miami, FL). It was iodinated with 125I by the iodine monochloride method, and The neuromuscular junction is well suited for studies of the the labeled diiodo a-BuTx (1251-aBuTx) was purified by development of chemically transmitting synapses. Only three chromatography (11).
    [Show full text]
  • Loss of Acetylcholine Receptor Clusters Induced by Treatment of Cultured Rat Myotubes with Carbachol
    The Journal of Neuroscience March 1966, 6(3): 691-700 Loss of Acetylcholine Receptor Clusters Induced by Treatment of Cultured Rat Myotubes with Carbachol Robert J. Bloch Department of Physiology, University of Maryland School of Medicine, Baltimore, Maryland 21201 Prolonged exposure to carbachol disrupts the acetylcholine re- of carbachol; (2) the cation flux into myotubes following the ceptor (AChR) clusters of cultured rat myotubes without causing conformational change; (3) the depolarization following cation myotube loss. The effect is reversible, and is dependent on tem- flux. I show that the second possibility, cation flux through the perature. Half-maximal cluster loss is achieved at 3 PM car- receptor channel, accounts for the destabilizing effect of car- bachol. Cluster loss is also caused by other agonists of the AChR bachol on AChR clusters. These results are consistent with the and is blocked by receptor antagonists. QX314 (a lidocaine de- idea that the stability of the AChR clusters of cultured rat myo- rivative), meproadifen, and fluphenazine also completely block tubes is dependent on the intracellular ionic milieu. cluster loss caused by carbachol. These results are consistent with the idea that cluster loss caused by carbachol and other Materials and Methods receptor agonists results from their interaction with the AChR, Methods for preparing myotube cultures, for staining them with tetra- and the consequent influx of cations into the myotubes. Several methylrhodamine-cu-bungarotoxin (R-BT; Ravdin and Axelrod, 1977), experiments suggest that extracellular Na+ and Ca*+ are re- and for analyzing AChR clusters have been presented in detail elsewhere quired, and that at least Na+ must permeate the AChR ion chan- (Bloch, 1979, 1983).
    [Show full text]
  • Degradation of Junctional and Extrajunctional Acetylcholine
    Proc. Natl. Acad. Sci. USA Vol. 76, No. 7, pp. 3547-3551, July 1979 Neurobiology Degradation of junctional and extrajunctional acetylcholine receptors by developing rat skeletal muscle (synapse development) JOE HENRY STEINBACH*, JOHN MERLIEt, STEPHEN HEINEMANN*, AND ROBERT BLOCH* *Neurobiology Department, The Salk Institute, P. 0. Box 1809, San Diego, California 92112; and tDepartment of Biological Science, University of Pittsburgh, Pittsburgh, Pennsylvania 15260 Communicated by Stephen W. Kuffler, April 20, 1979 ABSTRACT We have examined the rate of degradation of studied this question more thoroughly in diaphragms from rats, the total acetylcholine receptor content of diaphragm muscles 1 day old to adult, and found that junctional AcChoRs are of young rats and have found that even in muscles from 1-day- metabolically more stable than extrajunctional AcChoRs at all old rats some receptors are metabolically more stable than adult extrajunctional receptors. Further experiments have shown that ages examined. acetylcholine receptors at junctional regions from young rats are degraded slowly, whereas those in extrajunctional regions MATERIALS AND METHODS are degraded rapidly. The results demonstrate that junctional Preparation of t25I-Labeled a-Bungarotoxin. a-Bungaro- acetylcholine receptors in rat diaphragm are degraded at a slow rate characteristic of adult junctional receptors at all ages after toxin was purified from the venom of the krait Bungarus birth. multicinctus (Ross Allen Serpentarium, Miami, FL). It was iodinated with 125I by the iodine monochloride method, and The neuromuscular junction is well suited for studies of the the labeled diiodo a-BuTx (1251-aBuTx) was purified by development of chemically transmitting synapses. Only three chromatography (11).
    [Show full text]
  • Expression Cloning of an ATP Receptor from Mouse Neuroblastoma Cells
    Proc. Natl. Acad. Sci. USA Vol. 90, pp. 5113-5117, June 1993 Pharmacology Expression cloning of an ATP receptor from mouse neuroblastoma cells KEVIN D. LUSTIG, ANDREW K. SHIAU, ANTHONY J. BRAKE, AND DAVID JULIUS* Department of Pharmacology, Programs in Cell Biology and Neuroscience, University of California, San Francisco, CA 94143 Communicated by Stephen Heinemann, March 1, 1993 ABSTRACT Extracellular ATP activates cell-surface me- A more complete characterization ofthis putative family of tabotropic and ionotropic nucleotide (P2) receptors in vascular, P2 purinergic receptors has been hampered by the complete neural, connective, and immune tissues. These P2 receptors lack of specific P2 receptor antagonists, radioligands, and mediate a wealth of physiological processes, including nitric cloned receptor cDNAs. To circumvent this difficulty, we oxide-dependent vasodilation of vascular smooth muscle and have used a Xenopus laevis oocyte expression cloning strat- fast excitatory neurotransmission in sensory afferents. Al- egy (19, 20) to isolate a cDNA encoding a functional P2U though ATP is now recognized as a signaling molecule, the receptor from NG108-15 neuroblastoma x glioma hybrid cellular and molecular mechanisms underlying its actions have cells.t We have examined the agonist selectivity, signaling been difficult to study due to the absence ofselective P2 receptor properties, species origin, and tissue distribution of the antagonists and cloned receptor genes. Nonetheless, five mam- cloned P2U receptor. malian P2 receptor subtypes have been tentatively assigned based solely on agonist specificity and signaling properties. EXPERIMENTAL PROCEDURES Here we report the cloning of a mouse cDNA encoding a P2 receptor that shares striking homology with several G protein- Expression Cloning.
    [Show full text]
  • Q U a R T E R
    EUROSCIENCE NSUMMER 2006 QUARTERLY “The times demand that SfN Celebrates Opening of Its New we as neuroscientists Headquarters Building in Washington constantly advocate for The Society for Neuroscience cel- the funding necessary to ebrated its new headquarters build- achieve the exciting break- ing and office space in Washington, DC, with an opening gala on May 5. throughs envisioned by the Approximately 150 guests attended, Roadmap and the Blue- including past presidents, representa- print, and enabled by the tives from the Spanish and Italian embassies, SfN committee chairs, Human Genome Project.” NIH directors, and other leaders in the sciences. — SfN President Stephen Heinemann The evening’s events began in the (see page 2) building lobby, where SfN President Stephen Heinemann welcomed at- Stephen Heinemann and Edward Perl, SfN’s first presi- tendees to the dedication ceremony. dent, cut ribbon, formally opening the building. I N T H I S I S S U E “This new building represents many things to the Society. Among the most important is that it embodies the vision and mission shared by all of SfN’s leaders,” said Heinemann. “This building is a sign that SfN Celebrates Opening .............................. 1 neuroscience and the Society are committed for the long term to supporting and Message from the President ....................... 2 playing a role in the research enterprise, and to maintaining a strong presence in our nation’s Capital.” Cajal Mural Dedication ............................... 4 Neuroscience 2006 ..................................... 5 Past President Carol Barnes, head of SfN’s Real Estate Committee, spoke about the environmentally responsible strategies behind the headquarters’ construction. “As Society Programs .......................................
    [Show full text]
  • Stephen Francis Traynelis
    Stephen Francis Traynelis Address Department of Pharmacology 5025 Rollins Research Center, 1510 Clifton Road Emory University phone 404 727 0357 fax 404 727 0365 email [email protected] Education 1984 West Virginia University, Morgantown, WV B.S. Chemistry 1988 University of North Carolina, Chapel Hill, NC Ph.D. Pharmacology Research Training and Job Experience 1989-1991 University College London, London, UK. Postdoctoral Research with Prof. Stuart Cull-Candy, FRS, Department of Pharmacology 1992-1994 Salk Institute, La Jolla, CA. Postdoctoral Research with Prof. Stephen Heinemann, Director of the Molecular Neurobiology Laboratory 1994-2000 Assistant Professor, Department of Pharmacology, Emory University 2000-2006 Associate Professor, Department of Pharmacology, Emory University 2006- Professor, Department of Pharmacology, Emory University Scholarships, Awards, and Honors 2015- The Faculty of 1000 2015 The Emory 1% 2014 Elected a Fellow of the American Association for the Advancement of Science (AAAS) 2010 Founding member of Millipub Club, Emory University (faculty with papers having >1000 citations) 2010 One in One Hundred Mentors, Office of Postdoctoral Education, Emory School of Medicine 2008 Teaching Excellence Award, Dept Pharmacology, Emory School of Medicine 2007 Javits Award from NINDS st 2007 1 Annual Distinguished Alumni Award in Chemistry, West Virginia University 1997 President, Atlanta Chapter, Society for Neuroscience 1995 John Merck Scholar 1984 B.S. Chemistry, Summa Cum Laude 1980 John Moore Chemistry Scholarship, West
    [Show full text]
  • Dispersal and Reformation of Acetylcholine Receptor Clusters Of
    DISPERSAL AND REFORMATION OF ACETYLCHOLINE RECEPTOR CLUSTERS OF CULTURED RAT MYOTUBES TREATED WITH INHIBITORS OF ENERGY METABOLISM Downloaded from http://rupress.org/jcb/article-pdf/82/3/626/1073938/626.pdf by guest on 27 September 2021 ROBERT J . BLOCH From the Neurobiology Laboratory, The Salk Institute, San Diego, California 92112 ABSTRACT The effects of energy metabolism inhibitors on the distribution of acetylcholine receptors (AChRs) in the surface membranes of non-innervated, cultured rat myotubes were studied by visualizing the AChRs with monotetramethylrhoda- mine-a-bungarotoxin . Incubation of myotubes with inhibitors of energy metabo- lism causes a large decrease in the fraction of myotubes displaying clusters of AChR . This decrease is reversible, and is dependent on temperature, the concen- tration of inhibitor, and the duration of treatment . Cluster dispersal is probably not the result of secondary effects on Ca" or cyclic nucleotide metabolism, membrane potential, cytoskeletal elements, or protein synthesis . Sequential obser- vations of identified cells treated with sodium azide showed that clusters appear to disperse by movement of receptors within the sarcolemma without accompa- nying changes in cell shape . AChR clusters dispersed by pretreating cells with sodium azide rapidly reform upon removal of the inhibitor . Reclustering involves the formation of small aggregates of AChR, which act as foci for further aggregation and which appear to be precursors of large AChR clusters . Small AChR aggregates also appear to be precursors of clusters which form on myotubes never exposed to azide. Reclustering after azide treatment does not necessarily occur at the same sites occupied by clusters before dispersal, nor does it employ only receptors which had previously been in clusters .
    [Show full text]
  • Repeated Administration of Amphetamine Or Cocaine Does Not Alter AMPA Receptor Subunit Expression in the Rat Midbrain Wenxiao Lu, M.D., Lisa M
    Repeated Administration of Amphetamine or Cocaine Does Not Alter AMPA Receptor Subunit Expression in the Rat Midbrain Wenxiao Lu, M.D., Lisa M. Monteggia, Ph.D., and Marina E. Wolf, Ph.D. We previously reported that ventral tegmental area (VTA) withdrawal time. GluR1 immunolabeling was further dopamine neurons are supersensitive to AMPA when examined in rats killed 16–18 hrs or 24 hrs after a single recorded three days after discontinuing repeated injection of amphetamine or repeated injections of saline, amphetamine or cocaine administration. By increasing amphetamine (5 mg/kg ϫ 5 days) or cocaine (20 mg/kg ϫ 7 dopamine cell activity, this may contribute to the induction days). No significant differences were observed in any of behavioral sensitization. The goal of this study was to region. Finally, neither repeated amphetamine or cocaine determine if increased sensitivity to AMPA reflects administration significantly altered GluR1 mRNA levels as increased AMPA receptor expression in the midbrain. quantified by reverse transcriptase-polymerase chain reaction. Immunolabeling for GluR1, GluR2, GluR2/3, and GluR4 Our results suggest that enhanced responsiveness of VTA was quantified by immunohistochemistry with 35S-labeled dopamine neurons to AMPA after withdrawal from repeated secondary antibodies in VTA, substantia nigra, and a stimulant administration involves mechanisms more complex transitional area. First, rats were treated for five days with than increased expression of AMPA receptor subunits. saline or amphetamine (5 mg/kg) and killed three or 14 days [Neuropsychopharmacology 26:1–13, 2002] after the last injection. No significant changes in © 2001 American College of Neuropsychopharmacology. immunolabeling were observed for any subunit at either Published by Elsevier Science Inc.
    [Show full text]
  • Immunoprecipitation, Immunoblotting, and Lmmunocytochemistry Studies Suggest That Glutamate Receptor 6 Subunits Form Novel Postsynaptic Receptor Complexes
    The Journal of Neuroscience, March 1995, 75(3): 2533-2546 Immunoprecipitation, Immunoblotting, and lmmunocytochemistry Studies Suggest That Glutamate Receptor 6 Subunits Form Novel Postsynaptic Receptor Complexes Ebrahim Mayat, Ronald S. Petralia, Ya-Xian Wang, and Robert J. Wenthold Laboratory of Neurochemistry, NIDCD, NIH, Bethesda, Maryland 20892 An antibody was made to a C-terminus peptide of the glu- specific ion channels (for a recent review, see Hollmann and tamate receptor 62 subunit and used to study the distri- Heinemann, 1994). According to pharmacological and subse- bution, biochemical properties, and developmental expres- quent binding studies, GluRs were classified into three main sion of the S receptor in rat brain. The antibody recognizes subtypes: the NMDA, a-amino-3-hydroxy-5-methyl-4-isoxazole both 61 and 62 but not AMPA, kainate, NMDA, and propionic acid (AMPA), and kainate (KA) receptors (for mGluRla glutamate receptor subunits based on Western reviews, seeMonaghan et al., 1989; Watkins et al., 1990; Young blot analysis of transfected HEK-293 cells. Western blot and Fagg, 1990). In the last 5 years, cloning studieshave led to analysis of brain showed a single immunoreactive band, the characterization of multiple subunits which comprise each migrating at M, = 114,000. lmmunoprecipitation of deter- of the three GluR subtypes (for reviews, see Nakanishi, 1992; gent-solubilized cerebellar membranes was done to deter- Sommer and Seeburg, 1992; Hollmann and Heinemann, 1994). mine if S is associated with other glutamate receptor sub- The AMPA receptor has four subunits,GluRl-4, or GluR-A to units and if it binds any of the common excitatory amino -D (Hollmann et al., 1989; Boulter et al., 1990; Keinanen et al, acid ligands.
    [Show full text]
  • NIDA Monograph 126 Molecular Approaches to Drug Abuse
    RESEARCHNational Institute on Drug Abuse MONOGRAPH SERIES Molecular Approaches to Drug Abuse Research Volume II 126 U.S. Department of Health and Human Services Public Health Service National Institutes of Health Molecular Approaches to Drug Abuse Research Volume II: Structure, Function, and Expression Editor: Theresa N.H. Lee, Ph.D. NIDA Research Monograph 126 1992 U.S. DEPARTMENT OF HEALTH AND HUMAN SERVICES Public Health Service Alcohol, Drug Abuse, and Mental Health Administration National Institute on Drug Abuse 5600 Fishers Lane Rockville, MD 20857 ACKNOWLEDGMENT This monograph is based on the papers and discussions from a technical review on “Molecular Approaches to Drug Abuse Research” held on July 30-31, 1991, in Bethesda, MD. The technical review was sponsored by the National Institute on Drug Abuse (NIDA). COPYRIGHT STATUS The National Institute on Drug Abuse has obtained permission from the copyright holders to reproduce certain previously published material as noted in the text. Further reproduction of this copyrighted material is permitted only as part of a reprinting of the entire publication or chapter. For any other use, the copyright holder’s permission is required. All other material in this volume except quoted passages from copyrighted sources is in the public domain and may be used or reproduced without permission from the Institute or the authors. Citation of the source is appreciated. Opinions expressed in this volume are those of the authors and do not necessarily reflect the opinions or official policy of the National Institute on Drug Abuse or any other part of the U.S. Department of Health and Human Services.
    [Show full text]
  • Annual Meeting
    EUROSCIENCE NFALL 2006 QUARTERLY SEE INSIDE FOR THE “We now risk losing our FY 2006 ANNUAL PROGRESS REPORT leadership role in science and Message from the President technology, which has in Neuroscientists Must Take Responsibility the past set the example for for Educating the Public, Advocacy other nations to follow.” The coming months provide an extraordinary chance for Society for Neuroscience members to educate the public about the importance of neuroscience and biomedi- — SfN President Stephen Heinemann cal research. We have three important opportunities: the weeks leading up to the mid-term Congressional and other elections on November 7, 2006; Brain Awareness Week next March; and fulfilling a mandate to enlist business leaders in support of federal funding for National Institutes of Health (NIH) and National Science Foun- dation budgets early in the new year. I N T H I S I S S U E As you know, the need for public education about neuroscience and science in gener- al has never been more urgent. The United States now ranks 16 of 17 nations in the proportion of 24-year-olds who earn degrees in science and engineering, according to Message from the President ....................... 1 Continued on page 2. Q & A with Raynard Kington ...................... 1 Election Results ........................................... 8 In SfN Interview, Raynard Kington, NIH Blueprint Update .................................. 9 Deputy Director, National Institutes Results of Member Survey On Open Access, Online Publishing........... 10 of Health, Discusses Key Issues Fifth FENS Forum a Success ...................... 11 NQ: Some in the scientific community worry that the NIH roadmap is taking money away from R01 grants.
    [Show full text]